Lab #11: Respiratory Physiology

Lab #11: Respiratory Physiology Background The respiratory system enables the exchange of O2 and CO2 between the cells and the atmosphere, thus enabli...

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Lab #11: Respiratory Physiology Background The respiratory system enables the exchange of O2 and CO2 between the cells and the atmosphere, thus enabling the intake of O2 into the body for aerobic respiration and the release of CO2 for regulation of body fluid pH. In this exercise, we will examine ventilation of the lungs to enable the exchange of air between the alveoli and the atmosphere, and also explore the rate of CO2 release from the lungs as a mechanism for controlling pH.

Mechanics of Lung Ventilation. Air flow into and out of the lungs is driven by pressure differences between the atmospheric air and air in the lungs. When atmospheric pressure exceeds intrapulmonary pressure, air flows into the lungs, and when intrapulmonary pressure exceeds atmospheric pressure, air flows out of the lungs. Changes in intrapulmonary pressure are driven by changing the volume of the lungs—per Boyle’s Law, the pressure exerted by a given amount of gas at a constant temperature is inversely proportional to the volume of that gas. Thus increasing the volume of the lungs will decrease intrapulmonary pressure, whereas decreasing lung volume will increase intrapulmonary pressure. During tidal ventilation, air is inspired by contracting certain muscles in the walls and floor of the thoracic cavity (Fig 11.1). As the diaphragm contracts, it pulls downward and forward, whereas when the external intercostals contract, they lift the ribs upward and laterally.

Fig 11.1. Relaxation of the inspiratory muscles drives tidal expiration (left), whereas forced expirations are driven by contraction of the expiratory muscles (right). From L. Sherwood, Fundamentals of Human Physiology. Brooks Cole.

The net result is an increase in the volume of the thoracic cavity. Since the lungs are adhered to the inner walls of the thoracic cavity, the lungs also expand. This decreases intrapulmonary pressure below atmospheric pressure, and air flows into the lungs along the pressure gradient. Tidal expiration is driven by the relaxation of the muscles used to drive tidal inspiration (Fig 11.2). As the diaphragm moves upward and backward and the ribs move downward and inward the overall volume of the thoracic cavity is reduced. This compression of the thoracic cavity, in turn, elevates intrapulmonary pressure above atmospheric pressure, and air flows out of the lungs. Additional amounts of air can be inspired or expired from the lungs with the contraction of additional muscles. Maximal inspirations are driven with contraction of muscles associated with the sternum and clavicle in addition to a full contraction of the diaphragm and external intercostals. Air can be forcibly expired from the lungs with contraction from the internal intercostals and a number of abdominal muscles (Fig 11.2).

Lung Volumes and Capacities.

Fig 11.1. Muscle contractions that drive tidal inspiration. From L. Sherwood, Fundamentals of Human Physiology. Brooks Cole

The amount of air contained in the lungs during ventilation can change considerably depending on what muscles are driving air flow and how forcefully they contract. The different amounts of air drawn into or out of the lungs by

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• 6000

Volume (ml)

IRV IC VC VT TLC ERV FRC RV 0 Primary Lung Volumes

Lung Capacities

Fig. 11.3. Illustration of a spirometer recording depicting measurements of the primary lung volumes (left) and the lung capacities (right)

contracting different groups of muscles are called primary lung volumes. Different combinations of the primary lung volumes, in turn provide us with lung capacities, which define either how much air is present in the lungs or how much air can be moved by the lungs under specific situations. There are four primary lung volumes (Fig 11.3), defined as follow. •





Residual Volume (RV). The residual volume is the amount of air that remains in the lungs following a maximal expiration, and can only be forced out of the lungs by collapsing the lungs. The RV for men is approximately 1200 ml and approximately 900 ml in women.

Tidal volume (VT). The tidal volume is the amount of air inspired (or expired) during normal tidal breathing. At rest, tidal volume in healthy adult men is approximately 500 ml, and about 400 ml in women. Tidal volume increases with activity to accommodate increased need for gas exchange. Inspiratory Reserve Volume (IRV). The inspiratory reserve volume is the volume of air that can be maximally inspired above the volume inspired tidally. Average IRV measurements at rest for men and women are approximately 3100 ml and 2400 ml, respectively. IRV decreases with exercise. Expiratory Reserve Volume (ERV). The expiratory reserve volume is the maximum volume of air that can forcibly expired beyond a normal tidal expiration. Average ERV at rest is approximately 1200 ml for men and 900 ml for women at rest. Like IRV, the ERV decreases when exercising.

There are also four lung capacities, each of which is the sum of two or more primary lung volumes. •







Total Lung Capacity (TLC). The total lung capacity is the maximum amount of air that can be held within the lungs at one time, and is the volume of air in the lungs following a maximal inspiration. TLC is the sum of all four primary volumes (TLC = IRV + VT + ERV +RV). Vital Capacity (VC). The vital capacity is the maximum amount of air that can be exchanged between the lungs and atmosphere in a single breath, and is the volume of air that can be forcibly expired from the lungs following a maximal expiration. The vital capacity is the sum of the three primary volumes that can be directly exchanged with the atmosphere (VC = IRV + VT + ERV). Inspiratory Capcity (IC). The inspiratory capacity is the maximum amount of air that can be inspired following a normal tidal expiration. It is the sum of the inspiratory reserve volume and the tidal volume (IC = IRV + VT). Functional Residual Capacity (FRC). The functional residual capacity is the volume of air that remains in the lung following a normal tidal expiration. It is the sum of the expiratory reserve volume and the residual volume (FRC = ERV + RV).

Measurements of Tidal Ventilation. The amount of air exchanged between the lungs and the atmosphere during tidal breathing is

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where VDS is the volume of the dead space (estimated to be 1/3 of the resting tidal volume).

Volume (ml)

5000 4000 3000

Air Flow Measurements.

2000 1000 0

0 FEV1 = (5000 ml -1000 ml) / 5000ml = 4000 ml / 5000 ml = 80%

1

2

3

Time (sec)

Fig 11.4. Illustration of a spirometer recording measuring forced expiratory volume.

determined influenced how much air is exchanged in each breath (the tidal volume) and how frequently breaths are take (the breathing rate). Measurements of tidal ventilation, therefore, must take both of these factors into account. One simple measurement of tidal ventilation is the minute volume (VM), which is the volume of air inspired through tidal breathing during in a one minute period of time. Minute volume is simply the product of the tidal volume (VT) and the breathing rate (f)

Efficient air exchange between the lungs and the atmosphere requires a) that the lungs be able to change volume effectively and b) air can pass through the respiratory passageways with relative ease. The ability of a person’s lungs to change in volume is reflected in their vital capacity measurement—individuals with larger vital capacities can change the volume of their lungs more that can those with smaller vital capacities. The ability of air to flow through the respiratory passages, in contrast is reflected in a measurement called the forced expiratory volume (FEVt), which is the percentage of the vital capacity that, after a maximal inspiration, can be forcibly expired in t seconds (Fig 11.4). FEVt can be calculated as the ratio of air forcibly expired in a designated time interval (Vt, not to be confused with tidal volume, VT) divided by the vital capacity (VC) and converted into a percentage.

VM = f × VT

FEVt =

The minute volume, however, overestimates the amount of air that is available for gas exchange. This is because not all of the air flowing into the lungs during inspiration flows into the alveoli; some of this air accommodates the increased volume of the respiratory passages during inspiration, and since these passages are not designed for gas exchange with the blood, they are considered to be physiological “dead space”. A better measurement for the amount of air flowing over the respiratory surfaces during tidal ventilation is alveolar ventilation (VA), sometimes called the minute alveolar volume, which is the amount of air entering the alveoli in a one minute period. Alveolar ventilation is calculated using a similar equation to that of the minute volume except that it corrects for the volume of the dead space: VA = f × (VT - VDS)

Vt VC

× 100%

A young adult can typically expire roughly 80% of their vital capacity within one second, 94% within two seconds, and 97% within three seconds. Vital capacity and FEVt measurements can be used to diagnose various types of air flow disorders. Abnormally low FEVt measurements (less than 90% the value predicted for an individual based on their age) may be indicative of an obstructive disorder. In an obstructive disorder, air flow through the respiratory passages is impeded by a narrowing of those passages, thus increasing resistance to air flow. Bronchiolar secretions and constriction of air passageways (See Fig 11.5) are common causes of obstructive disorders. On the other hand, abnormally low vital capacity (less than 80% the predicted value based on age, sex, and body size) may be indicative of a restrictive disorder. In a restrictive disorder, the lungs are unable to

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Fig 11.5. Asthma is an example of an obstructive lung disorder. Smooth muscle contraction in the respiratory passages reduce the diameter of the airways, increasing resistance to air flow through them. Image from http://www.drgreene.org/images/cg/19346.jpg

change volume enough to allow adequate air flow into and out of the alveoli. This could be caused by a loss of elasticity of the tissue, fluid within the alveoli, or an increase in the dead space of the lungs (see Fig 11.6). Note that a particular lung pathology could be both obstructive and restrictive. For example, in emphysema (Fig 11.7), the alveolar walls break down. This decreases the elasticity of the lungs, increases the dead space, and decreases the vital capacity, and is thus a restrictive disorder. The breakdown of the alveoli, however, also reduces structural supports for the bronchioles, thus the bronchioles may narrow or even collapse, creating obstruction to air flow.

Fig. 11.7. Cross section of a lung with emphysema. Note the numerous cavities formed by the collapse of alveolar walls. The result is an elevation in residual volume, a decrease in vital capacity, and elevated resistance to air flow in the respiratory passages. Image from http://www.medicdirect.co.uk/ images/emphysema_large.jpg

Carbon Dioxide Exchange and pH Balance. CO2 is an important factor in the regulation of pH in the human body. This is because CO2 in solution can reversibly react with water to form carbonic acid. CO2+ H2O ↔ H2CO3 Carbonic acid, in turn, may dissociate into bicarbonate and free hydrogen ion, in turn elevating the [H+] of the solution and lowering pH.

H2CO3 ↔ H+ + HCO3-

Fig 11.6. X rays of normal lungs (left) and lungs with pulmonary fibrosis (right). Pulmonary fibrosis, or scarring of the lung tissue, is a restrictive disorder. Interstitial spaces between the alveoli are filled with fibrous tissue, thus restricting the ability of the alveoli to expand. Moreover, the alveoli are often inflamed, resulting in fluid within the alveoli that reduce alveolar volume and increase diffusion distances. Images from alice.ucdavis.edu/ IMD/420C/films/cxr4.htm

CO2 is transported in the blood stream by three different means: as dissolved CO2 gas in the plasma, by binding to hemoglobin in the erythrocytes, and in the form of bicarbonate in the blood plasma. Both methods of transporting CO2 in the plasma can influence the pH of the plasma. Most of the bicarbonate present in blood plasma is not a result of spontaneous reactions

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Erythrocyte CO2 + H2O

(70%)

H2CO3 H+

(20%)

CO2 (from cells)

H2CO3

(carbonic anhydrase)

90% enters erythrocytes

HCO3-

Hb HCO3-

10% remains in plasma

CO2 + H2O

H2CO3

H+ + HCO3-

Fig 11.8. Diagram illustration the three means of CO2 transport in the blood. Note that some of the CO2 dissolved in the plasma can react spontaneously with water to form carbonic acid. Thus increased CO2 in the plasma tend to decrease plasma pH through increased carbonic acid formation.

between CO2 and H2O, but is manufactured by the erythrocytes (Fig 11.8). Roughly 90% of the CO2 released from the cells is absorbed by the erythrocytes. About 20% binds to hemoglobin, whereas the remaining 70% reacts with water to form carbonic acid in a reaction catalyzed by the enzyme carbonic anhydrase. The carbonic acid formed subsequently dissociates into H+ and bicarbonate. H+ binds to specific amino acid side chains on the hemoglobin, whereas the bicarbonate is transported out to the blood plasma. The bicarbonate formed can act as a buffer against pH changes due to the introduction of other acids, since increases in [H+] will tend to promote the binding of H+ to bicarbonate. The remaining 10% of the CO2 released by the cells can also influence blood pH. Some of this dissolved CO2 will spontaneously react with water to form carbonic acid, which in turn will dissociate into H+ and bicarbonate. Note that in this case the H+ is released into the plasma. The more dissolved CO2 present in the blood, the more H+ will be released into the plasma, and the lower the pH will be. Thus regulation of dissolved CO2 levels in the plasma is an important component of body fluid pH regulation. By modifying tidal ventilation and subsequent CO2 release into the atmosphere, dissolved CO2 levels in the blood can be tightly regulated and thus blood pH can be tightly regulated.

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Time difference between the two blue reference lines

Volume difference between the two blue reference lines

Fig 11.9. The Labscribe setup for measuring lung ventilation.

Experiment I: Lung Ventilation. A. Tidal volume, breathing rate, and alveolar ventilation measurements 1.

Place a disposable cardboard mouthpiece over one of the ends of the spirometer flow head attached to the iWorx unit.

2.

Go to the computer screen, and be sure the software (LabScribe) is running (Fig 11.9). The top tracing will display voltage changes from the transducer—ignore it for our exercise. The lower tracing converts these changes in voltage into volume changes, and you will be using this tracing for all of your measurements. Change the display time to 60 sec by selecting the EDIT menu from the top, then PREFERENCES, then enter the desired display time in the middle box of the top line.

3.

Click “START” in the top right corner of the screen.

4.

The subject should wait five seconds before beginning to breathe through the mouthpiece so the instrument can equilibrate correctly. Have the subject place the mouthpiece fully in their mouth and

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pinch their nostrils closed so that they breathe only through their mouth. The subject should breathe through the mouthpiece normally for ~70 seconds (your can keep track of this by the meter in the top left corner of the screen, then click “STOP” at the top right of the screen. If the tracing “stairclimbs” (i.e., keeps moving progressively up or down) during your recording ask your instructor for assistance. 5.

If the tracing on the lower screen is reversed (i.e., the tracing dips when the person breathes in), right click on the lower screen and select “INVERT”

6.

Count the number of inspirations made during the last 60 seconds of the recording (i.e., what is on the screen) to determine the respiratory frequency for this individual (see Fig 11.10).

7.

Select a single tidal breath in the recording. Drag one of the blue lines at the far right edge of the tracing over to the low point of this tidal breath, and drag the other blue line over to the peak of the tracing (see Fig 11.10). The difference in volume between these to points, showing just above the tracing to the right, is the tidal volume (VT). Measure the tidal volume for three separate breaths and record the average of these values.

8.

Calculate the alveolar ventilation using the respiratory frequency, the average tidal Fig. 11.10. Positioning Reference lines for volume, and assuming that the volume of determination of Tidal Volume (VT) the dead space (VDS) = 1/3 the average resting tidal volume. Remember: VA = RF × (VT – VDS)

9.

Have the subject exercise moderately by having them run up and down a staircase 2-3 times then run back to the lab (they should be fairly winded when they return). As soon as they return to the lab, repeat the procedures above and determine the respiratory frequency, tidal volume, and alveolar ventilation during exercise. NOTE: use the estimate for VDS calculated from resting tidal volume to calculate alveolar ventilation.

B. Lung volumes, capacities, and forced expiratory volume. 1.

Click “START” in the top right corner of the screen.

2.

After waiting five seconds, have the subject place the mouthpiece in their mouth and pinch their nostrils closed so that they breathe only through their mouth. The subject should take five normal tidal breaths through the mouthpiece with their noses pinched closed as you record. When they have expired their fifth tidal breath, they then should inspire as much air as they possibly can (the rest of the group should cheer them on), then expire as much air as quickly and forcibly as they possibly can (again, cheer them on as they are doing this). The subject must make sure their nostrils are pinched closed so that air escapes only through the mouthpiece. Only after the subject cannot force any more air out of their lungs should they remove the mouthpiece.

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3.

If the tracing on the lower screen is reversed (i.e., the tracing dips when the person breathes in), right click on the lower screen and select “INVERT”. You may also want to change the display time to 30 sec instead of 60 seconds. You may do so by selecting the EDIT menu from the top, then PREFERENCES, then enter the desired display time in the middle box of the top line.

4.

Using the blue lines, determine the tidal volume (VT) for this tracing based on the tidal breath immediately before the maximal inspiration (see Fig. 11.11). It should be similar to the average tidal volume recorded for that individual earlier.

5.

Determine the inspiratory reserve volume (IRV) by measuring the difference in volume from the peak of the tidal inspiration to the peak of the maximal inspiration (see Fig. 11.12).

6.

Determine the expiratory reserve volume (ERV) by measuring the difference in volume from the base of the tidal expiration to the base of the maximal expiration, per Fig. 11.13.

7.

Measure the vital capacity (VC) by measuring the difference in volume from the peak of the maximal inspiration to the base of the maximal expiration, per Fig. 11.14. Compare this value with the subject’s predicted vital capacity (based on their age, sex and height, see Appendix).

8.

Calculate the inspiratory capacity (IC) by either a) subtracting the expiratory reserve volume from the vital capacity or b) adding the tidal volume and inspiratory reserve volumes together.

9.

Estimate the residual volume (RV) and total lung capacity (TLC) for the subject by multiplying the volume of the vital capacity by the values based upon age given in Table 11.1.

Fig. 11.11. Positioning Reference lines for determination of Tidal Volume (VT)

Fig. 11.12. Positioning Reference lines for determination of Inspiratory Reserve Volume (IRV) .

Fig. 11.13. Positioning Reference lines for determination of Expiratory Reserve Volume (ERV).

10. Calculate the functional residual capacity (FRC) by adding

the residual volume and the expiratory reserve volume together. Table 11.1. Equations for estimating residual volume (RV) and total lung capacity (TLC) from measured vital capacity.

Fig. 11.14. Positioning reference lines for determination of Vital Capacity (VC).

Age 16-34 35-49 50-69

Estimated Residual Volume 0.250 × Vital Capacity 0.305 × Vital Capacity 0.445 × Vital Capacity

Estimated Total Lung Capacity 1.250 × Vital Capacity 1.305 × Vital Capacity 1.445 × Vital Capacity

From S.I. Fox, Laboratory Guide to Human Physiology, 9th ed, McGraw Hill

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Figure11.15. Positioning reference lines for determination of the volume of air forcibly expired in 1 second (V1). Note that the left-hand line needs to be positioned at the start of the forced expiration, then the right-hand line should be positioned as close to 1.000 sec after the left-hand line as possible (arrow).

C. Forced Expiratory Volume To calculate the forced expiratory volume (FEV1), return to the recording of the vital capacity from the previous experiment. Place one of the blue lines on the peak of the maximal expiration at the exact point at which the person begins to exhale (see figure below). Position the second line to the right of the first so that the time meter in the top left hand corner of the screen (“T2-T1”) is as close to 0:0:1.000 (1 second) as possible (see Fig 11.15). Record the volume of air expired in 1 second (upper right hand of lower tracing), then divide this value by the vital capacity, and convert to a percentage per the following equation. FEV1sec = V1sec/VC × 100%

Table 11.2. Predicted FEV1sec values. Age

Predicted FEV1sec (%VC)

18-29 30-39 40-44 45-49 50-54 55-64

80-82% 77-78% 75.50% 74.50% 73.50% 70-72%

From S.I. Fox, Laboratory Guide to Human Physiology, 9th ed, McGraw Hill.

Compare the value obtained with the subject’s predicted FEV1 values (based on age) in Table 11.2.

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Fig 11.16. Progressive changes in the color of a phenolphthalein solution as CO2 is added to the solution and pH decreases from alkaline to neutral pH. Images from http://www.chemistry.wustl.edu/~courses/genchem/Labs/AcidBase/phph.htm.

Experiment II: CO2 Production and Acid-Base Balance. A. Elevated Blood [CO2] and its Effect on pH Obtain a pair of beakers containing ~150-200 ml of our test solution, which consists of distilled water, a small amount of NaOH to generate a weakly alkaline pH, and a few drops of phenolphthalein. The color of phenolphthalein changes with pH; at a pH > 7.0, phenolphthalein is pink, but below pH 7.0 it is colorless. Place two straws into one of the two beakers. Have the subject place the straws in their mouth and start timing. The subject should breathe tidally inspiring through the nose then expiring through their mouth, blowing bubbles into the solution. Be sure to breathe as normally and tidally as possible (this is not a bubble-blowing contest!). Time how long it takes for the solution to lose all pink coloration (Fig 11.16). Once completed, have the person go for a quick run outside or up and down the staircase to elevate their respiration (they should be panting when they return). Immediately give them the second beaker of solution and repeat the procedure. Note any difference in the time it takes to turn the solution clear.

B. Reduced Blood [CO2] and its Effect on Respiration Have someone in your lab group sit quietly for one minute, then record their resting breathing rate for 30 sec. Multiply this value by two to obtain the breathing rate (breaths/min) and record. Then have them hyperventilate for 10 seconds, increasing both tidal volume and breathing frequency as much as possible. Once they have completed their hyperventilation, record their breathing rate once again for a period of 30 sec and record the breathing rate in breaths/min. Note any difference in breathing rate.

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APPENDIX: Predicted Vital Capacity - Females HEIGHT (cm) AGE 16 17 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 50 52 54 56 58 60 62 64 66 68 70 72

146 2950 2935 2920 2890 2860 2830 2800 2775 2745 2715 2685 2655 2630 2600 2570 2540 2510 2480 2455 2425 2395 2365 2335 2305 2280 2250 2220 2190 2160 2130

148 2990 2975 2960 2930 2900 2870 2840 2810 2780 2750 2725 2695 2665 2635 2605 2575 2545 2515 2485 2455 2425 2400 2370 2340 2310 2280 2250 2220 2190 2160

150 3030 3015 3000 2970 2940 2910 2880 2850 2820 2790 2760 2730 2700 2670 2640 2610 2580 2550 2520 2490 2460 2430 2400 2370 2340 2310 2280 2250 2220 2190

152 3070 3055 3040 3010 2980 2950 2920 2890 2860 2825 2795 2765 2735 2705 2675 2645 2615 2585 2555 2525 2495 2460 2430 2400 2370 2340 2310 2280 2250 2220

154 3110 3095 3080 3050 3020 2985 2960 2930 2895 2865 2835 2805 2770 2740 2710 2680 2650 2620 2590 2555 2530 2495 2460 2430 2405 2370 2340 2310 2280 2250

156 3150 3135 3120 3090 3060 3025 3000 2965 2935 2900 2870 2840 2810 2775 2745 2715 2685 2650 2625 2590 2560 2525 2495 2460 2435 2400 2370 2340 2310 2280

158 3190 3175 3160 3130 3095 3065 3035 3000 2970 2940 2910 2875 2845 2810 2870 2930 2715 2685 2655 2625 2590 2560 2525 2495 2465 2430 2400 2370 2340 2310

160 3230 3215 3200 3170 3135 3100 3070 3040 3010 2975 2945 2910 2880 2850 2815 2785 2750 2715 2690 2655 2625 2590 2560 2525 2495 2465 2430 2400 2370 2335

162 3270 3255 3240 3210 3175 3140 3110 3070 3045 3015 2980 2950 2915 2885 2850 2820 2785 2750 2720 2690 2655 2625 2590 2560 2525 2495 2465 2430 2400 2365

164 3310 3295 3280 3250 3215 3180 3150 3115 3085 3050 3020 2985 2950 2920 2885 2855 2820 2785 2755 2720 2690 2655 2625 2590 2560 2525 2495 2460 2425 2395

166 3350 3335 3320 3290 3255 3220 3190 3155 3120 3090 3055 3020 2990 2955 2920 2890 2855 2820 2785 2755 2720 2690 2655 2625 2590 2555 2525 2490 2455 2425

168 3390 3375 3360 3330 3290 3260 3230 3190 3160 3125 3090 3060 3025 2990 2955 2925 2890 2855 2820 2790 2755 2720 2690 2655 2620 2585 2555 2520 2485 2455

170 3430 3415 3400 3370 3330 3300 3265 3230 3195 3160 3130 3095 3060 3025 2990 2960 2925 2890 2855 2820 2790 2755 2720 2685 2655 2620 2585 2550 2515 2480

172 3470 3455 3440 3410 3370 3335 3300 3270 3235 3200 3165 3130 3095 3060 3025 2995 2960 2925 2890 2855 2820 2790 2750 2720 2685 2650 2615 2580 2545 2510

174 3510 3495 3480 3450 3410 3375 3340 3305 3270 3235 3200 3165 3130 3095 3060 3030 2995 2960 2925 2890 2855 2820 2785 2750 2715 2680 2645 2610 2575 2540

176 3550 3535 3520 3490 3450 3415 3380 3345 3310 3275 3240 3205 3170 3135 3100 3060 3030 2995 2955 2925 2885 2855 2815 2780 2745 2710 2675 2640 2605 2570

178 3590 3575 3560 3525 3490 3455 3420 3380 3345 3310 3275 3240 3205 3170 3135 3095 3060 3030 2990 2955 2920 2885 2850 2810 2775 2740 2705 2670 2635 2600

180 3630 3615 3600 3565 3530 3490 3455 3420 3385 3350 3310 3275 3240 3205 3170 3130 3095 3060 3025 2990 2950 2920 2880 2845 2810 2770 2735 2700 2665 2630

182 3670 3655 3640 3605 3570 3530 3495 3460 3420 3385 3350 3310 3275 3240 3205 3165 3130 3095 3060 3020 2985 2950 2920 2875 2840 2805 2765 2730 2695 2660

184 3715 3695 3680 3645 3610 3570 3530 3495 3460 3425 3385 3350 3310 3275 3240 3200 3165 3130 3090 3055 3020 2980 2945 2915 2870 2835 2800 2760 2725 2685

186 3755 3740 3720 3685 3650 3610 3570 3535 3495 3460 3425 3385 3350 3310 3275 3235 3200 3160 3125 3090 3050 3015 2975 2940 2900 2865 2825 2795 2755 2715

188 3800 3780 3760 3720 3685 3650 3610 3570 3535 3495 3460 3420 3385 3345 3310 3270 3235 3195 3155 3125 3085 3045 3010 2970 2935 2895 2860 2820 2780 2745

190 3840 3820 3800 3760 3725 3685 3650 3610 3570 3535 3495 3460 3420 3380 3345 3305 3270 3230 3190 3155 3115 3080 3040 3000 2965 2925 2890 2850 2810 2775

192 3880 3860 3840 3800 3765 3725 3685 3650 3610 3570 3535 3495 3455 3420 3380 3340 3305 3265 3225 3190 3150 3110 3075 3035 2995 2955 2920 2880 2840 2805

194 3920 3900 3880 3840 3800 3725 3725 3685 3645 3610 3570 3530 3490 3455 3415 3375 3340 3300 3260 3220 3180 3145 3105 3065 3025 2990 2950 2910 2870 2830

74

2100

2130

2160

2190

2220

2245

2275

2305

2335

2365

2390

2420

2450

2475

2505

2535

2565

2590

2620

2650

2680

2710

2740

2765

2795

1 inch = 2.54 cm

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APPENDIX Predicted Vital Capacity - Males HEIGHT (cm) AGE 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 50 52 54 56 58 60 62 64 66 68 70 72

146 3765 3740 3710 3680 3635 3605 3575 3550 3520 3475 3445 3415 3385 3360 3315 325 3255 3210 3185 3155 3125 3080 3050 3020 2990 2950 2920 2890 2860

148 3820 3790 3760 3730 3685 3655 3625 3595 3565 3525 3495 3465 3435 3405 3360 3330 3300 3255 3225 3195 3165 3125 3095 3060 3030 2990 2960 2930 2900

150 3870 3840 3810 3780 3735 3705 3675 3645 3615 3570 3540 3510 3480 3450 3405 3375 3345 3300 3270 3240 3210 3165 3135 3110 3080 3030 3000 2970 2940

152 3920 3890 3860 3830 3785 3755 3725 3695 3665 3620 3585 3555 3525 3495 3450 3420 3390 3345 3315 3285 3255 3210 3175 3150 3120 3070 3040 3010 2980

154 3975 3940 3910 3880 3835 3805 3775 3740 3710 3665 3635 3605 3575 3540 3495 3465 3435 3390 3355 3325 3295 3250 3220 3190 3160 3110 3080 3050 3020

156 4025 3995 3960 3930 3885 3855 3820 3790 3760 3715 3680 3650 3620 3590 3540 3510 3480 3430 3400 3370 3340 3290 3260 3230 3200 3150 3120 3090 3060

158 4075 4045 4015 3980 3935 3905 3870 3840 3810 3760 3730 3695 3665 3635 3585 3555 3525 3475 3445 3415 3380 3335 3300 3270 3240 3190 3160 3130 3100

160 4130 4095 4065 4030 3985 3955 3920 3890 3855 3810 3775 3745 3710 3680 3630 3600 3570 3520 3490 3455 3425 3375 3345 3310 3280 3230 3200 3170 3140

162 4180 4145 4115 4080 4035 4000 3970 3935 3905 3855 3825 3790 3760 3725 3675 3645 3615 3565 3530 3500 3465 3420 3385 3350 3320 3270 3240 3210 3180

164 4230 4200 4165 4135 4085 4050 4020 398 3950 3905 3870 3840 3805 3770 3725 3690 3655 3610 3575 3540 3510 3460 3430 3390 3360 3310 3280 3250 3210

166 4285 4250 4215 4185 4135 4100 4070 4035 4000 3950 3920 3885 3850 3820 3770 3735 3700 3650 3620 3585 3550 3500 3470 3440 3400 3350 3320 3290 3250

168 4335 4300 4265 4235 4185 4150 4115 4080 4050 4000 3965 3930 3900 3865 3815 3780 3745 3695 3660 3630 3595 3545 3500 3480 3440 3390 3360 3330 3290

170 4385 4350 4320 4285 4235 4200 4165 4130 4095 4045 4010 3980 3945 3910 3860 3825 3790 3740 3705 3670 3640 3585 3555 3520 3490 3440 3400 3370 3330

172 4440 4405 4370 4335 4285 4250 4215 4180 4145 4095 4060 4025 3990 3955 3905 3870 3835 3785 3750 3715 3680 3630 3595 3560 3530 3490 3440 3410 3370

174 4490 4455 4420 4385 4330 4300 4265 4230 4195 4140 4105 4070 4035 4000 3950 3915 3880 3830 3795 3760 3725 3670 3635 3600 3570 3510 3480 3450 3410

176 4540 4505 4470 4435 4380 4350 4310 4275 4240 4190 4155 4120 4085 4050 3995 3960 3925 3870 3835 3800 3765 3715 3680 3640 3610 3550 3520 3480 3450

178 4590 4555 4520 4485 4430 4395 4360 4325 4290 4225 4200 4165 4130 4095 4040 4005 3970 3915 3880 3845 3810 3755 3720 3680 3650 3600 3560 3520 3480

180 4645 4610 4570 4535 4480 4445 4410 4375 4340 4285 4250 4210 4175 4140 4085 4050 4015 3960 3925 3890 3850 3800 3760 3730 3690 3640 3600 3560 3520

182 4695 4660 4625 4585 4530 4495 4460 4425 4385 4330 4295 4260 4220 4185 4130 4095 4060 4005 3970 3930 3895 3840 3805 3770 3730 3680 3640 3600 3560

184 4745 4710 4675 4635 4580 4545 4510 4470 4435 4380 4340 4305 4270 4230 4175 4140 4105 4050 4010 3975 3940 3880 3845 3810 3770 3720 3680 3640 3600

186 4800 4760 4725 4685 4630 4595 4555 4520 4485 4425 4390 4350 4315 4280 4220 4185 4150 4090 4055 4020 3980 3925 3885 3850 3810 3760 3720 3680 3640

188 4850 4815 4775 4735 4680 4645 4605 4570 4530 4475 4435 4400 4360 4325 4270 4230 4190 4135 4100 4060 4025 3965 3930 3890 3850 3800 3760 3720 3680

190 4900 4865 4825 7490 4730 4695 4655 4615 4580 4520 4485 4445 4410 4370 4315 4275 4235 4180 4140 4105 4065 4010 3970 3930 3900 3840 3800 3760 3720

192 4955 4915 4875 4840 4780 4740 4705 4665 4625 4570 4530 4495 4455 4415 4360 4320 4280 4225 4185 4145 4110 4050 4015 3970 3940 3880 3840 3800 3760

194 5005 4965 4930 4890 4830 4790 4755 4715 4675 4615 4580 4540 4500 4460 4405 4365 4325 4270 4230 4190 4150 4095 4055 4020 3980 3920 3880 3840 3800

74

2820

2860

2900

2930

2970

3010

3050

3090

3130

3170

3200

3240

3280

3320

3360

3400

3440

3470

3510

3550

3590

3630

3670

3710

3740

1 inch = 2.54 cm

Lab #11: Respiration p.12